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Japan Atomic Energy Agency
日本原子力研究開発機構機関リポジトリ
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Title Magnetic structures of FeTiO3-Fe2O3 solid solution thin films studied by soft X-ray magnetic circular dichroism and ab initio multiplet calculations
Author(s) Hojo Hajime, Fujita Koji, Ikeno Hidekazu, Matoba Tomohiko, Mizoguchi Teruyasu, Tanaka Isao, Nakamura Tetsuya, Takeda Yukiharu, Okane Tetsuo, Tanaka Katsuhisa
Citation Applied Physics Letters, 104(11), p.112408_1-112408_5
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URL http://jolissrch-inter.tokai-sc.jaea.go.jp/search/servlet/search?5053039
DOI http://dx.doi.org/10.1063/1.4868638
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Copyright (2014) American Institute of Physics. This article may be downloaded for personal use only. Any other use requires prior permission of the author and the American Institute of Physics. The following article appeared in (Appl. Phys. Lett. 104, 112408 (2014)) and may be found at (http://dx.doi.org/10.1063/1.4868638).
Magnetic structures of FeTiO3-Fe2O3 solid solution thin films studied by soft X-raymagnetic circular dichroism and ab initio multiplet calculationsH. Hojo, K. Fujita, H. Ikeno, T. Matoba, T. Mizoguchi, I. Tanaka, T. Nakamura, Y. Takeda, T. Okane, and K.Tanaka Citation: Applied Physics Letters 104, 112408 (2014); doi: 10.1063/1.4868638 View online: http://dx.doi.org/10.1063/1.4868638 View Table of Contents: http://scitation.aip.org/content/aip/journal/apl/104/11?ver=pdfcov Published by the AIP Publishing Articles you may be interested in X-ray magnetic circular dichroism for Co x Fe4− x N (x = 0, 3, 4) films grown by molecular beam epitaxy J. Appl. Phys. 115, 17C712 (2014); 10.1063/1.4862517 Soft x-ray magnetic circular dichroism study of valence and spin states in FeT2O4 (T = V, Cr) spinel oxides J. Appl. Phys. 113, 17E116 (2013); 10.1063/1.4793769 X-ray magnetic circular dichroism in Co2FeGa: First-principles calculations Low Temp. Phys. 37, 684 (2011); 10.1063/1.3654132 X-ray magnetic circular dichroism in iron chalcogenides Fe 1 − x S : First-principles calculations J. Appl. Phys. 106, 123907 (2009); 10.1063/1.3269719 Electronic structure and magnetic properties of Al -doped Fe 3 O 4 films studied by x-ray absorption andmagnetic circular dichroism Appl. Phys. Lett. 86, 062504 (2005); 10.1063/1.1863450
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Magnetic structures of FeTiO3-Fe2O3 solid solution thin films studied by softX-ray magnetic circular dichroism and ab initio multiplet calculations
H. Hojo,1,a) K. Fujita,2,a) H. Ikeno,3 T. Matoba,2 T. Mizoguchi,4 I. Tanaka,5 T. Nakamura,6
Y. Takeda,7 T. Okane,7 and K. Tanaka2
1Materials and Structures Laboratory, Tokyo Institute of Technology, Yokohama, Kanagawa 226-8503, Japan2Department of Material Chemistry, Kyoto University, Nishikyo, Kyoto 615-8510, Japan3Fukui Institute for Fundamental Chemistry, Kyoto University, Sakyo, Kyoto 606-8103, Japan4Institute of Industrial Science, The University of Tokyo, 4-6-1 Meguro, Tokyo 153-8505, Japan5Department of Material Science and Engineering, Kyoto University, Sakyo, Kyoto 606-8501, Japan6Japan Synchrotron Radiation Research Institute, SPring-8, Sayo, Hyogo 679-5198, Japan7Japan Atomic Energy Agency, SPring-8, Sayo, Hyogo 679-5148, Japan
(Received 10 January 2014; accepted 27 February 2014; published online 18 March 2014)
The solid solutions between ilmenite (FeTiO3) and hematite (a-Fe2O3) have recently attracted
considerable attention as a spintronic material due to their interesting magnetic and electrical
properties. In this study, the electronic and magnetic structures of epitaxially grown
0.6FeTiO3�0.4Fe2O3 solid solution thin films were investigated by combining x-ray absorption
near-edge structure (XANES), x-ray magnetic circular dichroism (XMCD) for two different
crystallographic projections, and first-principles theoretical calculations. The Fe L-edge XANES and
XMCD spectra reveal that Fe is in the mixed-valent Fe2þ–Fe3þ states while Fe2þ ions are mainly
responsible for the magnetization. Moreover, the experimental Fe L-edge XANES and XMCD spectra
change depending on the incident x-ray directions, and the theoretical spectra explain such spectral
features. We also find a large orbital magnetic moment, which can originate the magnetic anisotropy of
this system. On the other hand, although the valence state of Ti was interpreted to be 4þ from the Ti
L-edge XANES, XMCD signals indicate that some electrons are present in the Ti-3d orbital, which are
coupled antiparallel to the magnetic moment of Fe2þ ions. VC 2014 AIP Publishing LLC.
[http://dx.doi.org/10.1063/1.4868638]
Development of materials that show both magnetic and
semiconducting properties is crucial for the realization of
semiconductor-based spintronic devices. Equally important
is to reveal the mechanism by which such properties arise.
The solid solutions between ilmenite (FeTiO3) and hematite
(a-Fe2O3) have recently attracted considerable attention1–7
due to their interesting magnetic and electronic properties
that are strongly dependent on ordering of cations as well as
composition.8–13 Ferrimagnetic semiconductors arise when
the arrangement of cations is ordered, whereas antiferromag-
netism is observed for disordered cation distribution. The
Curie temperature of ordered phases is higher than room
temperature except for compositions more than about
80 mol. % of FeTiO3. The p- and n-type semiconductors are
reached for compositions greater and less than 73 mol. % of
FeTiO3, respectively. Also, spin-polarized carrier was theo-
retically predicted to be present for the solid solution.14
The emergence of both ferrimagnetism and electronic
conduction in the solid solution has been qualitatively
explained assuming a simple ionic model, where the nominal
valence states of Fe ions and Ti ions in FeTiO3 are þ2 and
þ4, and that of Fe ions in Fe2O3 is þ3. FeTiO3 crystalizes in
corundum-derivative structure, in which alternate (0001)
layers of Fe2þ and Ti4þ ions are stacked along the c-axis. In
the solid solution of FeTiO3 with Fe2O3, it is generally
assumed on the basis of electrostatic energy minimization
that Fe3þ ions are equally distributed between the layers,
forming a charge ordered alternate (0001) layers of
(Fe2þþ Fe3þ) and (Ti4þþ Fe3þ). As a result of antiferro-
magnetic interaction between neighboring (0001) layers, the
magnetic moments of Fe3þ ions are canceled each other out,
and only Fe2þ ions contribute to the magnetization. This
assumption seems plausible from the compositional depend-
ence of the saturation magnetization, however, there has
been no direct experimental evidence except for one reported
very recently using aberration-corrected scanning transmis-
sion electron microscopy coupled to high-energy-resolution
electron energy-loss spectroscopy.15 Moreover, there have
been several experimental data, including x-ray magnetic
circular dichroism (XMCD),16 resonant x-ray photoemission
spectroscopy,16 x-ray emission spectroscopy,17,18 and reso-
nant inelastic x-ray scattering spectroscopy,19 which demon-
strate that the Ti ions in FeTiO3 intrinsically have some Ti3þ
characters. These results suggest necessity to revisit the elec-
tronic and magnetic structures of FeTiO3-Fe2O3 solid
solutions.
In this study, we have measured x-ray absorption near-
edge structure (XANES) and XMCD spectra at the Ti L2,3-
and Fe L2,3-edges for 0.6FeTiO3�0.4Fe2O3 solid solution thin
films in order to clarify the electronic and magnetic struc-
tures of the compound. Using recently-developed first-princi-
ples configuration interaction (CI) method,20–22 it is now
possible to predict XANES spectra of 3d transition metal
compounds without any empirical parameters. XMCD spec-
tra can also be calculated using the same method by taking
a)Authors to whom correspondence should be addressed. Electronic mail:
hhojo@msl.titech.ac.jp and fujita@dipole7.kuic.kyoto-u.ac.jp
0003-6951/2014/104(11)/112408/5/$30.00 VC 2014 AIP Publishing LLC104, 112408-1
APPLIED PHYSICS LETTERS 104, 112408 (2014)
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the energy of external magnetic fields into the Hamiltonian.
By comparing the experimental results with the
first-principles theoretical spectra, we discuss the electronic
and magnetic structures of the solid solution thin films. We
have also performed the same set of experiments for
0.8FeTiO3�0.2Fe2O3 thin film and got, essentially, the same
results as those for 0.6FeTiO3�0.4Fe2O3 thin film. Therefore,
we believe that the findings of this work are the general phe-
nomena of the FeTiO3-Fe2O3 solid solutions.
The thin film of 0.6FeTiO3�0.4Fe2O3 solid solution with
the ordered phase was epitaxially grown on an
a-Al2O3(0001) substrate using a pulsed laser deposition
method. The thin film was confirmed to be an n-type semi-
conductor and ferrimagnetic with the Curie temperature
>400 K. Details of the sample fabrication and characteriza-
tion are given in Ref. 2. In order to prevent surface deteriora-
tion, Au capping layer (�1.5 nm) was in-situ deposited after
the thin film growth.
XANES and XMCD measurements were performed at
soft x-ray beam line BL23SU23 and BL25SU24,25 at SPring-8
in the total electron yield (TEY) mode using the photon
beam with circular polarization rate of over 90%. XANES
spectra (lþ, l�) were obtained using helicity switching of
right-handed (lþ) and left-handed (l�) circularly polarized
x-rays under the applied magnetic field (H). XMCD spectra
are given by the difference between lþ and l�. The photon
k vector of the x-rays was set at 0� and 70� with respect to
the normal line of the film surface for out-of-plane and
in-plane measurements, respectively. Due to the presence of
strong magnetic anisotropy with an easy axis in the direction
parallel to the film surface, H¼ 10 T was applied to saturate
the magnetization for the out-of-plane measurements, while
H¼ 2 T was enough for the in-plane measurements.
Theoretical spectra at Fe and Ti L2,3-edges were calcu-
lated using a first-principles CI method.20–22 We performed
our calculations using model clusters composed of one tran-
sition metal ion and coordinating six oxide ions. The total
number of electrons in the cluster was obtained from the for-
mal charges. Possible valence states are þ3 and þ2 for Fe
and þ4 and þ3 for Ti, respectively. Therefore, the clusters
can be expressed as FeO69� for Fe3þ, FeO6
10� for Fe2þ,
TiO68� for Ti4þ, and TiO6
9� for Ti3þ. Due to the difficulty
in constructing a proper structure model for FeTiO3-Fe2O3
solid solution, the atomic positions including the lattice con-
stants were obtained from the experimentally reported values
of FeTiO3.26 The photon k vector was set at parallel (k//c)
and perpendicular (k? c) to the trigonal c axis of the cation
octahedra for the out-of-plane and in-plane calculations,
respectively. For the XMCD calculation, a magnetic field of
10 T was introduced parallel or antiparallel to the propaga-
tion direction of x-ray to induce the Zeeman splitting.
Figure 1 shows the Fe L2,3-edge XANES and XMCD
spectra of 0.6FeTiO3�0.4Fe2O3 solid solution thin films for
two propagation directions of incident x-ray at 150 K. At the
L3-edge, both XANES spectra are characterized by two
peaks around 708.5 and 710 eV as shown in Figs. 1(a) and
1(b). Hereafter, we will call them peaks A and B, respec-
tively. It is well known that Fe L2,3-edge XANES of Fe3þ in
oxygen octahedron is typically characterized by two peaks
around the transition energies of 708.5 and 710 eV, the latter
being the main peak. On the other hand, Fe2þ manifests only
one peak around 708.5 eV.27 The main peaks in experimental
XMCD spectra are located at the transition energy of peak
A, indicating that Fe2þ ions are mainly responsible for the
magnetization of the solid solution. This result strongly sup-
ports the model of the solid solution that the magnetic
moments of Fe3þ ions are canceled each other out and only
Fe2þ ions contribute to the magnetization. This is the first
direct experimental evidence for such a model. Note that
unignorable contribution of Fe3þ ions to XMCD seems to be
observed specially in the case of in-plane XMCD spectra.
Spin canting between antiferromagnetic Fe3þ ions could be
produced within the film plane. Comparing the in-plane and
the out-of-plane XANES and XMCD spectra, we also notice
that the fine structures are dependent on the incident direc-
tions: The A/B intensity ratios of XANES for the out-of-
plane incidence are larger (�0.75) than those for the in-plane
incidence (�0.72) [Figs. 1(a) and 1(b)], and the XMCD sig-
nals are broader for the in-plane incidence [Figs. 1(c) and
1(d)]. Incident-direction-dependence of XAENS and XMCD
is in essence a linear dichroism effect which originates from
the anisotropic spatial distribution of the Fe 3d electrons in a
low-symmetry environment. Such an effect cannot be
observed in bulk powder studies but is revealed due to the
epitaxial nature of the samples.
In order to clarify the origin of the incident direction de-
pendence of XANES and XMCD spectra, theoretical spectra
were calculated. Figure 2 shows the calculated Fe L2,3-edge
XANES and XMCD spectra of Fe2þ and Fe3þ in k//c and
k? c configurations. Hereafter, we assume that the main
peaks of each spectra, which are around 708.5 eV for Fe2þ
and 710 eV for Fe3þ, correspond to the peak A and B, respec-
tively. We find that the theoretical XANES and XMCD of
Fe2þ [red lines in Fig. 2] show drastic incident-angle depend-
ence compared with those of Fe3þ[black lines in Fig. 2]. This
can be interpreted as the result of asymmetric distribution of
3d electrons in Fe2þ (d6) compared to the symmetric distribu-
tion in Fe3þ (d5). As seen from Figs. 2(a) and 2(b), at the
L3-edge, Fe2þ in the k//c configuration mainly contributes to
peak A of the XANES spectrum while Fe2þ in the k? c con-
figuration is characterized by two peaks: One contributes to
the peak A, and the other lies between the peak A and B.
FIG. 1. Experimental (a) out-of-plane and (b) in-plane Fe L2,3-edge XANES
spectra of 0.6FeTiO3�0.4Fe2O3 solid solution thin films at 150 K. The corre-
sponding XMCD spectra are shown in (c) and (d), respectively.
112408-2 Hojo et al. Appl. Phys. Lett. 104, 112408 (2014)
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The theoretical XMCD spectrum of Fe2þ in the k? c config-
uration [Fig. 2(d)] also manifests two peaks at the L3-edge.
This can be the reason the experimental in-plane XMCD
gives broader signals; the broader spectrum obtained experi-
mentally can be decomposed into two peaks as suggested
theoretically. A closer look at the XANES of Fe2þ reveals
that the intensity of peak A, that is the average of lþ and l�,
is higher for the k//c configuration than that for the k? c con-
figuration. Therefore, the most probable interpretation of the
incident-angle dependence of the experimental XANES
should be the contribution of Fe2þ.
We have applied the XMCD sum rules28–30 to the exper-
imental results in order to estimate the ratio of orbital to spin
magnetic moment morb/mspin for each of the incident direc-
tions, which can be expressed as
morb
mspin þ 7hTzi¼ 2
3�
ðL2;3ðlþ � l�Þdx
ðL3ðlþ � l�Þdx� 2
ðL2ðlþ � l�Þdx
;
(1)
where hTzi is the expectation value of magnetic dipole
operator. This equation requires no information on the back-
ground of XANES, the average number of 3d holes, and the
degree of circular polarization of incident photons. The
morb/(mspinþ 7hTzi) ratios are 0.21 and 0.14 for in-plane and
out-of-plane directions, respectively, and larger contribution of
orbital moment was found for the in-plane incidence. We also
calculated the morb/(mspinþ 7hTzi) ratios for the theoretical
spectra and obtained a consistent result. Assuming uniaxial ani-
sotropy, the magnitude of hTzi was estimated to be �0.0016 lB
and 0.0008 lB for the out-of-plane and in-plane directions,
respectively, which should be much smaller than mspin. The
presence of larger morb for in-plane direction can be the origin
of the strong magnetic anisotropy observed in this system.2,4
Note that XANES recorded with the TEY mode typically suf-
fers from the saturation effect, leading to an underestimation of
the orbital moments.31 However, this does not affect our con-
clusion because the underestimation of orbital moment is more
significant for the in-plane incidence. Moreover, the values of
the morb/(mspinþ 7hTzi) ratios themselves are rather large (0.21
for in-plane direction) although the orbital moment is generally
quenched by the crystal field in transition metal oxides.
Namely, no small contribution of morb to the total magnetiza-
tion is expected in this material. Some of the previous experi-
mental data on the magnetization can be explained as the
contribution of morb. One example is the saturation magnetiza-
tion observed for bulk polycrystalline FeTiO3-Fe2O3 solid so-
lution. The value of saturation magnetization of the solid
solution is reported to be 4 lB/Fe2þ.32 At a glance, this is a rea-
sonable value theoretically expected from the spin-only contri-
bution. Nonetheless, considering the presence of strong
magnetic anisotropy in the crystal and the fact that grains with
an easy and hard axis are randomly distributed, the value of the
saturation magnetization should be smaller if only spins con-
tribute to the magnetization. Hence, it is suggested that the or-
bital as well as the spin contributes to the above-mentioned
value of saturation magnetization. Second example is on the
epitaxial thin film of the solid solution. We reported that the
saturation magnetization of the 0.63FeTiO3�0.37Fe2O3 epitax-
ial thin film is about 3 lB/f.u. along the axis of easy magnetiza-
tion,2 although the spin-only magnetization expected for that
composition is 2.52 lB/f.u. (4 multiplied by 0.63).
Figure 3 shows the Ti L2,3-edge XANES and XMCD
spectra of 0.6FeTiO3�0.4Fe2O3 solid solution thin films for two
directions of incident x-ray at 150 K. As shown in Figs. 3(a)
and 3(b), the experimental Ti L2,3-edge XANES spectra mani-
fest little incident angle dependence unlike the case of Fe. The
experimental XANES spectrum consists of four peaks, which
arise from the spin-orbit splitting of the Ti 2p level as well as
the crystal-field splitting of the Ti 3d level. This kind of spec-
trum has been interpreted to be Ti4þ in oxygen octahedron.33,34
Surprisingly, however, there exists undeniable XMCD signal
as seen from Figs. 3(c) and 3(d). One can also notice that the
XMCD spectra exhibit incident-direction dependence. The fine
structure of the in-plane XMCD is very similar to that
observed for bulk crystal of FeTiO3.16 In Fig. 3(e), we show
the in-plane Ti L2,3-edge XMCD hysteresis loop for
0.6FeTiO3�0.4Fe2O3 at 300 K. In order to eliminate the
non-magnetic background, magnetic field dependence of the
XMCD intensity was measured at the photon energy of 464.5
and 466 eV, and the difference between them is used for the
hysteresis loop.35 Figure 3(e) also illustrates the magnetic field
dependence of magnetization measured with a superconduct-
ing quantum interference device magnetometer.2 The shape of
the hysteresis loop is essentially the same as that of the mag-
netization. Therefore, the XMCD signals are not due to any ex-
perimental artifacts but suggest that the Ti ions in the solid
solution thin films intrinsically have magnetically polarized 3delectrons. Note that the sign of the XMCD hysteresis loop is
arbitrary, and we cannot tell if the magnetic moment of Ti is
parallel or anti-parallel to the magnetic field only from the ex-
perimental results.
To get an insight into the nature of Ti 3d electrons, theo-
retical Ti L2,3-edge XANES and XMCD spectra were
FIG. 2. Theoretical (a) out-of-plane and (b) in-plane Fe L2,3-edge XANES
spectra of Fe2þ and Fe3þ in FeTiO3 at 150 K. The corresponding XMCD
spectra are shown in (c) and (d) for Fe2þ and (e) and (f) for Fe3þ.
112408-3 Hojo et al. Appl. Phys. Lett. 104, 112408 (2014)
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133.53.174.31 On: Thu, 27 Aug 2015 08:24:42
derived for both k//c and k? c configurations assuming Ti4þ
(d0) and Ti3þ (d1) states. The results are shown in Fig. 4. The
calculated XANES spectra of Ti4þ [black lines in Figs. 4(a)
and 4(b)] agree well with the experimental ones. On the
other hand, the experimental Ti-L2,3 XMCD signals can be
better explained if we assume the presence of Ti3þ that is
coupled antiparallel rather than parallel with the magnetic
field [red lines in Figs. 4(c) and 4(d)]. These results suggest
the presence of Ti3þ in the solid solution and their contribu-
tion to the XMCD spectra. The Fe2þ ! Ti4þ charge transfer
caused by the Fe 3d-Ti 3d hybridization is generally
proposed as the origin of Ti3þ in FeTiO3. Although the trans-
fer mechanism is still controversial,19,36–38 theoretical calcu-
lations suggest that the Fe 3d minority-spin orbital
hybridizes with the Ti 3d orbital.36,39 Interestingly, this pic-
ture is consistent with our finding that Ti3þ is coupled anti-
parallel with the magnetic field. It should be noted that not
only Ti3þ but also Ti4þ give finite XMCD signal, even
though Ti4þ with (3d)0 configuration does not have magnetic
moment at the ground state. The Ti4þ XMCD signals are
enhanced by applying larger magnetic fields (not shown):
These results indicate that the Ti4þ XMCD signals originate
from the magnetic polarization at the final states of Ti-L2,3
XANES with (2p)5(3d)1 configuration. However, the fine
structures appearing in the experimental Ti-L2,3 XMCD
spectra cannot be explained only by the Ti4þ contribution.
Further systematic experiments should be carried out to
explore the origin and the nature of the electron in Ti 3dorbital.
In conclusion, we have investigated the electronic and
magnetic structures of epitaxially grown FeTiO3-Fe2O3 solid
solution thin films by combining XANES, XMCD for two
different crystallographic projections, and first-principles
theoretical calculations. The Fe L-edge XANES and XMCD
spectra reveal that Fe is in the mixed-valent Fe2þ–Fe3þ
states while Fe2þ ions are mainly responsible for the magnet-
ization of the solid solution. It is also demonstrated that the
first-principles calculation in combination with the angle
resolved XANES and XMCD spectra is a powerful tool to
study the anisotropy of Fe 3d electrons in the solid solution.
Applying XMCD sum rule, we find a large orbital magnetic
moment with anisotropy, which can be the origin of mag-
netic anisotropy. On the other hand, although the valence
state of Ti was interpreted to be 4þ from the Ti L2,3-edge
XANES, XMCD signals indicate that some electrons are
present in the Ti-3d orbital, which are coupled antiparallel to
the magnetic moment of Fe2þ ions.
The soft x-ray experiments at the SPring-8 were per-
formed with the approval of the JASRI (Proposal Nos.
2008B1797, 2009A1737, and 2010B1704) and the JAEA
(Proposal No. 2011B3874). This research was supported by
Grants-in-Aids for Scientific Research (B) (No. 22360273)
and Challenging Exploratory Research (No. 23655198) from
MEXT.
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FIG. 4. Theoretical (a) out-of-plane and (b) in-plane Ti L2,3-edge XANES
spectra of Ti4þ and Ti3þ in FeTiO3 at 150 K. The corresponding XMCD
spectra are shown in (c) and (d), respectively.
FIG. 3. Experimental (a) out-of-plane and (b) in-plane Ti L2,3-edge XANES
spectra of 0.6FeTiO3�0.4Fe2O3 at 150 K. The corresponding XMCD spectra
are shown in (c) and (d). (e) In-plane Ti L2,3-edge XMCD hysteresis loop of
0.6FeTiO3�0.4Fe2O3 at 300 K (closed circles). The photon energies used for
the XMCD hysteresis loop are indicated by arrows in the (d). Magnetic field
dependence of in-plane magnetization of 0.6FeTiO3�0.4Fe2O3 at 300 K (Ref.
2) is also shown for comparison (open circles).
112408-4 Hojo et al. Appl. Phys. Lett. 104, 112408 (2014)
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133.53.174.31 On: Thu, 27 Aug 2015 08:24:42
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